KR101178264B1 - Distribution board having earth-quake-proof function - Google Patents

Abstract

PURPOSE: A distribution board with earthquake-proof function is provided to block a shock wave directly delivered to internal electrical equipment by absorbing the shock wave applied to the horizontal direction. CONSTITUTION: Top LM guides(262,264) are arranged on the upper part of a middle plate(220) in Y-axis direction. Bottom LM bearings(252,254,256,258) are combined with bottom LM guides(242,244,246,248). Top LM bearings(272,274,276,278) are coupled to a top plate(230). Bottom tension springs(282,284,286,288) are parallel to a bottom plate. Top tension springs(292,294,296,298) are parallel to the middle plate.

Description

DISTRIBUTION BOARD HAVING EARTH-QUAKE-PROOF FUNCTION}

The present invention relates to a switchgear having a seismic function, and more particularly, to a switchgear having a seismic function for absorbing a shock wave, such as an earthquake wave applied in the horizontal direction to attenuate the horizontal shock wave applied to the switchgear.

In general, switchgear equipment is a power supply device that supplies the power required for apartments, buildings, schools, factories, ports, etc. by converting extra high pressure to low pressure. In other words, the high voltage of 3,300V or 6,600V should be received from the substation distribution line and transformed to commercial voltage again.In particular, in the electric equipment of large-scale buildings, the equipment that receives 22.9kV special high voltage and transforms it into commercial voltage is the switchgear. .

Most switchgear equipment includes a transformer, an optimal operation controller and a power monitoring controller of the transformer, and is manufactured in a single case of high and low pressure type having a multilayer structure to block external moisture or foreign substances and to facilitate construction. do.

In particular, the power monitoring controller installed inside the high and low voltage integrated switchgear processes the sensing values of the temperature sensor and the current voltage sensor to extract information such as operating temperature, load rate, phase loss, power factor, harmonic rate, and unbalance rate of the high voltage transformer. It can be notified to the administrator through the LCD display attached to the power monitoring controller, and also transmitted to the remote management system through the communication interface device.

1 is a schematic diagram schematically showing a switchgear according to the prior art.

Referring to FIG. 1, the switchboard according to the prior art includes a case 10 installed on the ground C, a door 20 configured to open and close at a side surface of the case 10, and an inside of the case 10. The electrical device 30 is installed, the fixing member 40 is a conductor fixed to the inner upper side of the case 10, and the cable 50 for connecting the fixing member 40 and the electrical device 30 The power supplied by the power company is sent to the electric device 30 through the cable 50. At this time, the fixing member 40 is fixed to the upper side of the case 10 through the insulator 60.

However, since the switchgear according to the prior art is fixedly installed on the ground, when an earthquake occurs, the shock wave is transmitted to the switchgear as it is, and the electric equipment installed inside the switchgear is damaged, so that a stable power supply cannot be provided where power is needed. This results in electric shock.

Accordingly, the technical problem of the present invention is to solve such a conventional problem, and an object of the present invention is a distribution panel case including a distribution panel, an MCC panel (Motor Control Center Panel), a low panel, a high panel, a transformer panel and a special panel. It is to provide a switchgear having a seismic function for supporting and absorbing the shock wave applied in the horizontal direction of the shock wave, such as seismic waves, to attenuate the horizontal shock wave applied to the switchgear.

In order to realize the object of the present invention, a switchgear having a seismic function according to an embodiment includes a switchgear case and a switchgear mounting table for supporting the switchgear case and blocking shock waves from being applied to the switchgear case. The switchboard mounting plate may include a lower plate, an intermediate plate, an upper plate, a plurality of lower EL guides, a plurality of lower EL bearings, a plurality of upper EL guides, a plurality of upper EL bearings, a plurality of lower tension springs, and a plurality of lower tension springs. Upper tension springs. The bottom plate is fixed to the floor of the building. The intermediate plate is disposed above the lower plate. The upper plate is disposed on the intermediate plate and fastened to the bottom surface of the switchboard case. The lower EL guides are disposed in the X-axis direction on the lower plate. The lower LM bearings are slide coupled to each of the lower LM guides and fastened to the intermediate plate. The upper LM guides are disposed in parallel to each other in the Y-axis direction on the upper portion of the intermediate plate, it is disposed perpendicular to the lower LM guides when viewed on the XY plane. The upper LM bearings are slide coupled to each of the intermediate LM guides and fastened to the upper plate. The lower tension springs are disposed in parallel with the lower plate, one side of each of which is fastened to the lower plate and each of the other side of the lower plate is fastened to the intermediate plate. The upper tension springs are disposed parallel to the intermediate plate, one side of each of which is fastened to the middle plate and each other of the other side of the upper plate is fastened. Each of the lower tension springs is orthogonal to each of the upper tension springs when viewed on the XY plane.

In one embodiment, the lower LM guides are arranged in two rows, the upper LM guides are arranged in two rows, when viewed in the XY plane the lower LM guides and the upper LM guides may be arranged in a well sperm shape. have.

In one embodiment, the lower tension springs may be composed of four, disposed radially when viewed on the XY plane, the upper tension springs may be composed of four, disposed in a rhombus shape when viewed on the XY plane. .

In one embodiment, the lower tension springs are composed of a first tension spring, a second tension spring, a third tension spring and a fourth tension spring, and the upper tension springs are the fifth tension spring, the sixth tension spring, and the seventh tension spring. It consists of a tension spring and an 8th tension spring, and when it observes on an XY plane, it is orthogonal to the said 1st tension spring and the said 5th tension spring, and orthogonal to the said 2nd tension spring and the 6th tension spring, and the said It may be orthogonal to the third tension spring and the seventh tension spring, and orthogonal to the fourth tension spring and the eighth tension spring.

In one embodiment, the lower LM guides are composed of a first LM guide, a second LM guide, a third LM guide and a fourth LM guide, the upper LM guide is composed of a fifth LM guide and a six LM guide ,

The fifth LGM may be orthogonal to the first and second LGM guides, and the sixth ELM guides may be orthogonal to the third and fourth LGM guides.

According to the switchgear having such a seismic function, it supports the switchgear case and absorbs the shock wave applied in the horizontal direction among the shock waves such as the earthquake wave to attenuate the horizontal shock wave applied to the switchgear to block the shock wave from being directly transmitted to the internal electrical equipment. By doing so, it is possible to prevent the occurrence of a short circuit due to damage to the electrical equipment.

1 is a schematic diagram schematically showing a switchgear according to the prior art.
Figure 2 is a schematic diagram for explaining a switchgear having a seismic function according to an embodiment of the present invention.
3 is an exploded perspective view for explaining the switchboard mounting table shown in FIG.
4 is a perspective view for explaining the LM guide and LM bearing shown in FIG.
5 is an exploded perspective view for explaining the LM guide and LM bearing shown in FIG.
6 is a schematic view of the switchboard mounting table in a normal state.
7 is a schematic diagram for explaining the shock wave attenuation operation of the switchboard mounting table when the shock wave is applied in the 3 o'clock direction.
8 is a schematic diagram for explaining the shock wave attenuation operation of the switchboard mounting table when the shock wave is applied in the 2 o'clock direction.
9 is a schematic diagram for explaining the shock wave attenuation operation of the switchboard mounting table when the shock wave is applied in the 5 o'clock direction.
10 is a schematic view for explaining the shock wave attenuation operation of the switchboard mounting table when the shock wave is applied in the 12 o'clock direction.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in more detail with reference to the accompanying drawings. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It should be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Like reference numerals are used for like elements in describing each drawing. In the accompanying drawings, the dimensions of the structures are enlarged to illustrate the present invention in order to clarify the present invention.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In this application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a part or a combination thereof is described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Also, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

Figure 2 is a schematic diagram for explaining a switchgear having a seismic function according to an embodiment of the present invention.

Referring to FIG. 2, a switchgear having a seismic function according to an embodiment of the present invention supports a switchgear case 100 and the switchgear case 100, and a shock wave generated by an earthquake or the like is applied to the switchgear case 100. It includes a switchgear board 200 to block the loss.

In the present embodiment, the switchboard mounting table 200 includes three plates arranged to overlap each other and a plurality of tension springs disposed between the plates to attenuate shock waves such as earthquake waves applied from the bottom.

3 is an exploded perspective view for explaining the switchboard mounting table 200 illustrated in FIG. 2.

2 and 3, the switchboard mounting table 200 according to the present embodiment includes a lower plate 210, an intermediate plate 220, an upper plate 230, and lower L guides 242, 244, 246 and 248. ), Lower LM bearings 252, 254, 256, 258, upper LM guides 262, 264, upper LM bearings 272, 274, 276, 278, lower tension springs 282, 284, 286 288, and top tension springs 292, 294, 296, and 298.

For convenience of description, each of the lower plate 210, the intermediate plate 220 and the upper plate 230 has a long side and a short side are disposed on the XY plane. In this case, long sides of each of the lower plate 210, the middle plate 220, and the upper plate 230 are parallel to the X axis, and the lower plate 210, the middle plate 220, and the upper plate ( 230 It is assumed that each short side is parallel to the Y axis. In addition, it is assumed that the intersection of the X-axis and the Y-axis is disposed on the central axis of each of the lower plate 210, the intermediate plate 220, and the upper plate 230.

Accordingly, each of the lower plate 210, the intermediate plate 220, and the upper plate 230 may be divided into one quadrant, two quadrants, three quadrants, and four quadrants. In the present embodiment, the LM guide used is a key component that is indispensable for machine tools and automation equipments such as NC lathe machining centers, and is a vertical transfer device that enables repetitive linear movement of the machine. In this embodiment, the LM guides are arranged in parallel with the bottom surface, and thus operate as a horizontal transfer device.

The lower plate 210 is fixed to the bottom surface. Although not shown, a plurality of holes are formed in the lower plate 210, and screws (not shown) are penetrated to be fixed to the bottom surface. Fastening grooves for fastening the lower LM guides 242, 244, 246 and 248 and lower tension springs 282, 284, 286 and 288 on an upper surface of the lower plate 210. Fastening protrusions are formed.

The intermediate plate 220 is disposed on the lower plate 210. Fastening grooves for fastening the lower L bearings 252, 254, 256, and 258 and lower tension springs 282, 284, 286, and 288 on the lower surface of the intermediate plate 220. Fastening protrusions are formed. Fastening grooves for fastening the upper LM guides 262 and 264 and fastening protrusions for fastening the upper tension springs 292, 294, 296, and 298 are formed on an upper surface of the intermediate plate 220. do.

The upper plate 230 is disposed on the intermediate plate 220 and fastened to the bottom surface of the switchboard case. Fastening grooves for fastening the upper L bearings 272, 274, 276, and 278 and lower tension springs 292, 294, 296, and 298 for fastening of the upper plate 230. Fastening protrusions are formed.

The lower LM guides 242, 244, 246, and 248 are disposed in the X-axis direction on the lower plate 210. The lower LM guides 242, 244, 246, and 248 include a first LM guide 242, a second LM guide 244, a third LM guide 246, and a fourth LM guide 248.

Specifically, the first LM guide 242 is fastened to one quadrant of the lower plate 210 in parallel with the X-axis direction. The second LM guide 244 is fastened to two quadrants of the lower plate 210 in parallel with the X-axis direction. The third LM guide 246 is fastened to three quadrants of the lower plate 210 in parallel with the X-axis direction. The fourth LM guide 248 is fastened to four quadrants of the lower plate 210 in parallel with the X-axis direction. In the present exemplary embodiment, although the lower LM guides 242, 244, 246, and 248 are shown as being configured with four, it is obvious that the lower L guides may be configured with two.

The lower L bearings 252, 254, 256, and 258 are slide-coupled to each of the lower L guides 242, 244, 246, and 248 and fastened to the intermediate plate 220. In the present embodiment, slide coupling means sliding along one axis after coupling. Each of the lower L bearings 252, 254, 256, and 258 is coupled to each of the lower L guides 242, 244, 246, and 248 and slides in one axial direction (for example, in the X axis direction). . The lower L bearings 252, 254, 256, and 258 include a first L bearing 252, a second L bearing 254, a third L bearing 256, and a fourth L bearing 258.

Specifically, the first L-bearing 252 is coupled to the lower surface portion of the intermediate plate 220 corresponding to one quadrant of the intermediate plate 220, and is coupled to one quadrant of the lower plate 210. It is coupled to the first LM guide 242 and moves in a sliding manner in the + X-axis direction or the X-axis direction.

The second L bearing 254 is coupled to a lower surface of the intermediate plate 220 corresponding to two quadrants of the intermediate plate 220, and the second L bearing 254 is coupled to two quadrants of the lower plate 210. Coupled to the LM guide 244 is moved in a sliding manner in the + X-axis direction or X-axis direction.

The third L bearing 256 is coupled to a lower surface of the intermediate plate 220 corresponding to three quadrants of the intermediate plate 220 and the third quadrant coupled to three quadrants of the lower plate 210. It is coupled to the LM guide 246 and moves in a sliding manner in the + X-axis direction or the X-axis direction.

The fourth L bearing 258 is coupled to a lower surface of the intermediate plate 220 corresponding to the fourth quadrant of the intermediate plate 220, and the fourth L bearing 258 is coupled to the fourth quadrant of the lower plate 210. Coupled to the LM guide 248 is moved in a sliding manner in the + X-axis direction or X-axis direction.

The upper LM guides 262 and 264 are disposed in parallel with each other in the Y-axis direction on the upper portion of the intermediate plate 220, and the lower LM guides 242, 244, 246 and 248 when viewed on an XY plane. Is placed perpendicular to the. The upper LM guides 262 and 264 include a fifth LM guide 262 and a sixth LM guide 264.

Specifically, the fifth LM guide 262 is fastened to one quadrant and two quadrants of the lower plate 210 in parallel with the Y-axis direction. The fifth LM guide 262 is disposed perpendicular to the first LM guide 242 and the second LM guide 244 when viewed from the XY plane.

The sixth EL guide 264 is fastened to three quadrants and four quadrants of the lower plate 210 in parallel with the Y-axis direction. The sixth LM Guide 264 is disposed perpendicular to the third LM Guide 246 and the third LM Guide 246 when viewed from the XY plane.

The upper LM bearings 272, 274, 276, and 278 are slide coupled to each of the intermediate LM guides and fastened to the upper plate 230. The upper L bearings 272, 274, 276, and 278 include a fifth L bearing 272, a sixth L bearing 274, a seventh L bearing 276, and an eighth L bearing 278.

Specifically, the fifth L-bearing 272 is coupled to the lower surface portion of the upper plate 230 corresponding to one quadrant of the upper plate 230, and is coupled to one quadrant of the intermediate plate 220. It is coupled to the fifth LM guide 262 and moves in a sliding manner in the + Y-axis direction or the Y-axis direction.

The sixth LM bearing 274 is coupled to a lower surface of the upper plate 230 corresponding to two quadrants of the upper plate 230 and the fifth coupled to two quadrants of the intermediate plate 220. Coupled to the LM guide 262 is moved in a sliding manner in the + Y-axis direction or Y-axis direction.

The seventh LMB bearing 276 is coupled to a lower surface portion of the upper plate 230 corresponding to three quadrants of the upper plate 230 and the sixth coupled to three quadrants of the intermediate plate 220. Coupled to the LM guide 264 is moved in a sliding manner in the + Y-axis direction or Y-axis direction.

The eighth L-bearing 278 is coupled to the lower surface of the upper plate 230 corresponding to the four quadrants of the upper plate 230 and the sixth quadrature coupled to the four quadrants of the intermediate plate 220. Coupled to the LM guide 264 is moved in a sliding manner in the + Y-axis direction or Y-axis direction.

The lower tension springs 282, 284, 286, and 288 are disposed in parallel with the lower plate 210, each of which is fastened to the lower plate 210 and each of the other sides is the intermediate plate 220. ) Is fastened. The lower tension springs 282, 284, 286, and 288 include a first tension spring 282, a second tension spring 284, a third tension spring 286, and a fourth tension spring 288. Disposed radially.

Specifically, the first tension spring 282 is disposed corresponding to one quadrant between the lower plate 210 and the intermediate plate 220. When viewed on the XY plane, the first tension spring 282 is disposed at an inclination angle of approximately -45 degrees with respect to the X axis. One side of the first tension spring 282 is fastened to the upper surface of the lower plate 210, the other side of the first tension spring 282 is fastened to the lower surface of the intermediate plate 220.

The second tension spring 284 is disposed corresponding to two quadrants between the lower plate 210 and the intermediate plate 220. When viewed on the XY plane, the second tension spring 284 is disposed at an inclination angle of approximately +45 degrees with respect to the X axis. One side of the second tension spring 284 is fastened to an upper surface of the lower plate 210, and the other side of the second tension spring 284 is fastened to a lower surface of the intermediate plate 220.

The third tension spring 286 is disposed corresponding to the three quadrants between the lower plate 210 and the intermediate plate 220. When viewed on the XY plane, the third tension spring 286 is disposed at an inclination angle of approximately +135 degrees with respect to the X axis. One side of the third tension spring 286 is fastened to an upper surface of the lower plate 210, and the other side of the third tension spring 286 is fastened to a lower surface of the intermediate plate 220.

The fourth tension spring 288 is disposed corresponding to the quadrant between the lower plate 210 and the intermediate plate 220. When viewed on the XY plane, the fourth tension spring 288 is disposed at an inclination angle of approximately −135 degrees with respect to the X axis. One side of the fourth tension spring 288 is fastened to an upper surface of the lower plate 210, and the other side of the fourth tension spring 288 is fastened to a lower surface of the intermediate plate 220.

In the drawing, one side of each of the first tension spring 282, the second tension spring 284, the third tension spring 286, and the fourth tension spring 288 is surrounded by the lower plate 210. It is fastened to the area, the other side is shown in the dotted line that is fastened to the center area of the intermediate plate 220. However, one side of each of the first tension spring 282, the second tension spring 284, the third tension spring 286, and the fourth tension spring 288 is a central region of the intermediate plate 220. The other side may be fastened to a peripheral area of the lower plate 210.

The upper tension springs 292, 294, 296, and 298 are disposed in parallel with the intermediate plate 220, each of which is fastened to the intermediate plate 220, and each of the other sides is the upper plate 230. ) Is fastened. The upper tension springs 292, 294, 296, and 298 include a fifth tension spring 292, a sixth tension spring 294, a seventh tension spring 296, and an eighth tension spring 298. It is arranged in a rhombus shape.

Specifically, the fifth tension spring 292 is disposed corresponding to one quadrant between the intermediate plate 220 and the upper plate 230. When viewed on the XY plane, the fifth tension spring 292 is disposed at an inclination angle of −45 degrees with respect to the X axis. One side of the fifth tension spring 292 is fastened to an upper surface of the intermediate plate 220, and the other side of the fifth tension spring 292 is fastened to a lower surface of the upper plate 230. When viewed on the XY plane, the fifth tension spring 292 is substantially perpendicular to the first tension spring 282.

The sixth tension spring 294 is disposed corresponding to the two quadrants between the intermediate plate 220 and the upper plate 230. When viewed on the XY plane, the sixth tension spring 294 is disposed at an inclination angle of +45 degrees with respect to the X axis. One side of the sixth tension spring 294 is fastened to an upper surface of the intermediate plate 220, and the other side of the sixth tension spring 294 is fastened to a lower surface of the upper plate 230. When viewed on the XY plane, the sixth tension spring 294 is substantially perpendicular to the second tension spring 284.

The seventh tension spring 296 is disposed corresponding to the three quadrants between the intermediate plate 220 and the upper plate 230. When viewed on the XY plane, the seventh tension spring 296 is disposed in parallel with the fifth tension spring 292. One side of the seventh tension spring 296 is fastened to an upper surface of the intermediate plate 220, and the other side of the seventh tension spring 296 is fastened to a lower surface of the upper plate 230. When viewed on the XY plane, the seventh tension spring 296 is substantially perpendicular to the third tension spring 286.

The eighth tension spring 298 is disposed corresponding to the quadrant between the intermediate plate 220 and the upper plate 230. When viewed on the XY plane, the eighth tension spring 298 is disposed parallel to the sixth tension spring 294. One side of the eighth tension spring 298 is fastened to an upper surface of the intermediate plate 220, and the other side of the eighth tension spring 298 is fastened to a lower surface of the upper plate 230. When viewed on the XY plane, the eighth tension spring 298 is substantially perpendicular to the fourth tension spring 288.

In the drawing, when observing the switchboard mounting table 200 according to the present embodiment on the XY plane, the fifth tension spring 292, the sixth tension spring 294, the seventh tension spring 296 and the fifth One side of each of the 8 tension springs 298 is fastened adjacent to an imaginary horizontal line (for example, the X axis) that divides the middle plate 220 up and down, and the other side is left and right of the middle plate 220. The fastening adjacent to the virtual vertical line (for example, Y-axis) which divides is shown by the dotted line. However, one side of each of the first tension spring 282, the second tension spring 284, the third tension spring 286, and the fourth tension spring 288 is fastened adjacent to the vertical line. The side may be fastened adjacent to the horizontal line.

4 is a perspective view for explaining the LM guide and LM bearing shown in FIG. 5 is an exploded perspective view for explaining the LM guide and LM bearing shown in FIG. For convenience of description, the first LM guide 242 and the first LM bearing 252 will be described. However, it is obvious that other LM guides or other LM bearings may have the same structure.

4 and 5, the first LM guide 242 has a rod shape and a rail is formed so that the first LM bearings 252 are coupled to both sides and slide. The rail is a groove retracted from the side of the first LM guide 242. A plurality of fastening holes (not shown) are formed in the first LM guide 242 and fastened to the lower plate 210 by screws.

The first L bearing 252 is a carriage 252a, a steel ball 252b, a square nut 252c, an end-plate 252d, a lubricant reservoir 252e, a front steel 252f, a plurality of screws Including a 252g and a lubricating oil nipple (252h), the slide is coupled to the first LM guide 242 and fastened to the intermediate plate 220.

The carriage 252a is coupled to a rail formed in the first LM guide 242, and four fastening holes (not shown) are formed at an upper portion thereof, such that four screws SC1, SC2, SC3, It is fastened to the said intermediate plate 220 by SC4).

The steel ball 252b is disposed between the carriage 252a and the rail formed in the first LM guide 242 so that the first LM bearing 252 smoothly moves on the first LM guide 242. Play a role in doing so.

The square nut 252c is disposed between the end-plate 252d and the carriage 252a and is fastened to a thread formed in the lubricant nipple 252h to fix the lubricant nipple 252h.

The end-plate 252d is fastened to the carriage 252a to prevent the steel ball 252b from flowing out.

The lubricant reservoir 252e is disposed between the end plate 252d and the front steel 252f to store lubricant supplied through the lubricant nipple 252h.

The front steel 252f surrounds the lubricant reservoir 252e through engagement with the end-plate 252d.

Hereinafter, a shock wave canceling operation by the switchboard mounting table will be described when a shockwave such as an earthquake wave is applied to the switchgear having the seismic function according to the present invention in various directions.

6 is a schematic view of the switchboard mounting table 200 in a normal state. For convenience of description, the lower plate guides 242, 244, 246 and 248 and the lower plate bearings are omitted by omitting the illustration of the intermediate plate 220 and the upper plate 230 in the switchboard mounting board 200 observed on the XY plane. 252, 254, 256, 258, upper LM guides 262, 264, upper LM bearings 272, 274, 276, 278, lower tension springs 282, 284, 286, 288 and upper tension The springs 292, 294, 296, 298 are shown to be transmitted.

Referring to FIG. 6, the first LM guide 242 and the second LM guide 244 are fastened to the lower plate 210 in parallel with each other. Specifically, the first LM guide 242 is fastened on one quadrant of the lower plate 210, and the second LM guide 244 is fastened on two quadrants of the lower plate 210. In this case, the first L-bearing member 252 fastened to the intermediate plate 220 is slide-coupled to the first L-guide 242, and the second L-bearing member 254 fastened to the intermediate plate 220 may be formed of the first L bearing 254. 2 is coupled to the LM guide 244.

The third LM guide 246 and the fourth LM guide 248 are fastened to the lower plate 210 in parallel with each other. Specifically, the third LM guide 246 is fastened on three quadrants of the lower plate 210, and the fourth LM guide 248 is fastened on four quadrants of the lower plate 210. At this time, the third L-bearing member 256 fastened to the intermediate plate 220 is slide-coupled to the third L-guide 246, and the fourth L-bearing member 258 fastened to the intermediate plate 220 is the A fourth slide is coupled to the LM guide 248.

The fifth LM guide 262 and the sixth LM guide 264 are fastened to the intermediate plate 220 in parallel with each other. Specifically, the fifth LM guide 262 is fastened to the first and second quadrants of the intermediate plate 220, the sixth LM guide 264 is the third and fourth quadrant of the intermediate plate 220 Is fastened to the top. At this time, the fifth LM bearing 272 and the sixth LM bearing 274 fastened to the upper plate 230 are slide-coupled to the fifth LM guide 262 and are fastened to the upper plate 230. The LM bearing 276 and the eight LM bearing 278 are slide-coupled to the sixth LM guide 264. Accordingly, the first through fourth LG guides 242, 244, 246 and 248, which are lower L guides, and the fifth and sixth LG guides 262 and 264, which are upper L guides, are disposed in a well sperm shape.

A first tension spring 282, a second tension spring 284, a third tension spring 286, and a fourth tension spring 288 are disposed between the lower plate 210 and the intermediate plate 220. The plate 210 is connected to the intermediate plate 220. In addition, a fifth tension spring 292, a sixth tension spring 294, a seventh tension spring 296, and an eighth tension spring 298 are disposed between the intermediate plate 220 and the upper plate 230. The intermediate plate 220 and the upper plate 230 are connected. In FIG. 6, the lower tension springs of the first to fourth tension springs 282, 284, 286 and 288 and the upper tension springs of the fifth to eighth tension springs 292, 294, 296 and 298 are shown. Is simplified.

When viewed on the XY plane, the first tension spring 282 and the fifth tension spring 292 are disposed perpendicular to each other, and the second tension spring 284 and the sixth tension spring 294 are disposed perpendicular to each other. . In addition, when viewed on the XY plane, the third tension spring 286 and the seventh tension spring 296 are disposed perpendicular to each other, and the fourth tension spring 288 and the eighth tension spring 298 are perpendicular to each other. Is placed.

7 is a schematic view for explaining the shock wave attenuation operation of the switchboard mounting table 200 when the shock wave is applied in the 3 o'clock direction.

6 and 7, when a shock wave such as an earthquake wave is applied to the switchboard mounting table 200 in the 3 o'clock direction, the lower plate 210 fixed to the bottom surface moves by the first length in the 3 o'clock direction. 7, the first to fourth tension springs 282, 284, 286 and 288, which are the lower tension springs, and the fifth to eighth tension springs 292, 294, 296, and 298 that are the upper tension springs. Is simplified. In FIG. 7, the expansion or contraction of the tension springs 282, 284, 286, 288, 292, 294, 296, 298 is described as relative length.

When the lower plate 210 moves by the first length, the intermediate plate 220 connected to the lower plate 210 through the first to fourth tension springs 282, 284, 286 and 288, which are lower tension springs. Moves in the 3 o'clock direction by a second length smaller than the first length. This is because the first tension spring 282 and the second tension spring 284 are contracted, and the third tension spring 286 and the fourth tension spring 288 are expanded to absorb a portion of the shock wave. As the shock wave is absorbed, the intermediate plate 220 moves by the second length.

When the intermediate plate 220 moves by the second length, the upper plate 230 connected to the intermediate plate 220 through the fifth to eighth tension springs 292, 294, 296, and 298, which are upper tension springs. Moves in the 3 o'clock direction by a third length smaller than the second length. This is because the fifth tension spring 292 and the sixth tension spring 294 are contracted, but the seventh tension spring 296 and the eighth tension spring 298 are inflated, so that the shock wave transmitted through the intermediate plate 220 is extended. This is because the remaining part is absorbed again. The third length may be zero.

As described above, the shock wave is primarily absorbed by the first to fourth tension springs 282, 284, 286, and 288, which are lower tension springs, even when the shock wave is applied to the switchboard mount 200 in the 3 o'clock direction. And transmitted to the intermediate plate 220, the shock wave transmitted to the intermediate plate 220 is absorbed by the upper tension springs 292, 294, 296, and 298 so that the shock wave is not transmitted to the upper plate 230. Fine shock waves can be transmitted. Therefore, the switchboard case disposed on the switchboard mounting table 200 is not adversely affected by the shock wave.

8 is a schematic view for explaining the shock wave attenuation operation of the switchboard mounting table 200 when the shock wave is applied in the 2 o'clock direction.

6 and 8, when a shock wave such as an earthquake wave is applied to the switchboard mounting table 200 in the 2 o'clock direction, the lower plate 210 fixed to the bottom surface moves by the fourth length in the 2 o'clock direction. 8, the first to fourth tension springs 282, 284, 286 and 288, which are the lower tension springs, and the fifth to eighth tension springs 292, 294, 296 and 298 which are the upper tension springs. Is simplified. In FIG. 8, the expansion or contraction of the tension springs 282, 284, 286, 288, 292, 294, 296, 298 is described as relative length.

When the lower plate 210 moves by the fourth length, the intermediate plate 220 connected to the lower plate 210 through the first to fourth tension springs 282, 284, 286 and 288, which are lower tension springs. Moves in the 2 o'clock direction by a fifth length smaller than the fourth length. This is because the first tension spring 282 and the second tension spring 284 are contracted, and the third tension spring 286 and the fourth tension spring 288 are expanded to absorb a portion of the shock wave. As the shock wave is absorbed, the intermediate plate 220 moves by the fifth length.

When the intermediate plate 220 moves by the fifth length, the upper plate 230 connected to the intermediate plate 220 through the fifth to eighth tension springs 292, 294, 296 and 298, which are upper tension springs. Moves by a sixth length smaller than the fifth length in the 2 o'clock direction. This is because the fifth tension spring 292 and the sixth tension spring 294 are contracted, but the seventh tension spring 296 and the eighth tension spring 298 are inflated, so that the shock wave transmitted through the intermediate plate 220 is extended. This is because the remaining part is absorbed again. The sixth length may be zero.

As described above, even if the shock wave is applied to the switchboard mounting table 200 in the 2 o'clock direction, the shock wave is primarily absorbed by the first to fourth tension springs 282, 284, 286, and 288, which are lower tension springs. And transmitted to the intermediate plate 220, the shock wave transmitted to the intermediate plate 220 is absorbed by the upper tension springs 292, 294, 296, and 298 so that the shock wave is not transmitted to the upper plate 230. Fine shock waves can be transmitted. Therefore, the switchboard case disposed on the switchboard mounting table 200 is not adversely affected by the shock wave.

9 is a schematic diagram for explaining the shock wave attenuation operation of the switchboard mounting table 200 when the shock wave is applied in the 5 o'clock direction.

6 and 9, when a shock wave such as an earthquake wave is applied to the switchboard mounting table 200 in the 5 o'clock direction, the lower plate 210 fixed to the bottom surface moves by the seventh length in the 5 o'clock direction. 9, the first to fourth tension springs 282, 284, 286 and 288, which are the lower tension springs, and the fifth to eighth tension springs 292, 294, 296 and 298 that are the upper tension springs. Is simplified. In FIG. 9, the expansion or contraction of the tension springs 282, 284, 286, 288, 292, 294, 296, 298 is described as relative length.

When the lower plate 210 moves by the seventh length, the intermediate plate 220 connected to the lower plate 210 through the first to fourth tension springs 282, 284, 286 and 288, which are lower tension springs. Moves in the 5 o'clock direction by an eighth length smaller than the seventh length. This is because the first tension spring 282 and the second tension spring 284 are contracted, and the third tension spring 286 and the fourth tension spring 288 are expanded to absorb a portion of the shock wave. According to the absorption of the shock wave, the intermediate plate 220 is moved by an eighth length.

When the intermediate plate 220 moves by the eighth length, the upper plate 230 connected to the intermediate plate 220 through the upper tension springs 292, 294, 296, and 298 may move to the eighth in the 5 o'clock direction. Move by the ninth length smaller than the length. This is because the fifth tension spring 292 and the sixth tension spring 294 are contracted, but the seventh tension spring 296 and the eighth tension spring 298 are inflated, so that the shock wave transmitted through the intermediate plate 220 is extended. This is because the remaining part is absorbed again. The ninth length may be zero.

As described above, the shock wave is primarily absorbed by the first to fourth tension springs 282, 284, 286, and 288, which are lower tension springs, even when the shock wave is applied to the switchboard mounting table 200 in the 5 o'clock direction. And transmitted to the intermediate plate 220, the shock wave transmitted to the intermediate plate 220 is absorbed by the upper tension springs 292, 294, 296, and 298 so that the shock wave is not transmitted to the upper plate 230. Fine shock waves can be transmitted. Therefore, the switchboard case disposed on the switchboard mounting table 200 is not adversely affected by the shock wave.

10 is a schematic view for explaining the shock wave attenuation operation of the switchboard mounting table 200 when the shock wave is applied in the 12 o'clock direction.

6 and 10, when a shock wave such as an earthquake wave is applied to the switchboard mounting table 200 in the 12 o'clock direction, the lower plate 210 fixed to the bottom surface moves by the tenth length in the 12 o'clock direction. In FIG. 10, the lower tension springs of the first to fourth tension springs 282, 284, 286, 288 and the upper tension springs of the fifth to eighth tension springs 292, 294, 296, 298 are shown. Is simplified. In FIG. 10, the expansion or contraction of the tension springs 282, 284, 286, 288, 292, 294, 296, 298 is described as relative length.

When the lower plate 210 moves by the tenth length, the intermediate plate 220 connected to the lower plate 210 through the first to fourth tension springs 282, 284, 286 and 288, which are lower tension springs. Moves by the eleventh length smaller than the tenth length in the 12 o'clock direction. This is because the first tension spring 282 and the second tension spring 284 are contracted, and the third tension spring 286 and the fourth tension spring 288 are expanded to absorb a portion of the shock wave. As the shock wave is absorbed, the intermediate plate 220 moves by the eleventh length.

When the intermediate plate 220 moves by the second length, the upper plate 230 connected to the intermediate plate 220 through the fifth to eighth tension springs 292, 294, 296, and 298, which are upper tension springs. Is moved by the thirteenth length smaller than the eleventh length in the 12 o'clock direction. This is because the fifth tension spring 292 and the sixth tension spring 294 are contracted, but the seventh tension spring 296 and the eighth tension spring 298 are inflated, so that the shock wave transmitted through the intermediate plate 220 is extended. This is because the remaining part is absorbed again. The thirteenth length may be zero.

As described above, the shock wave is primarily absorbed by the first to fourth tension springs 282, 284, 286 and 288, which are lower tension springs, even when the shock wave is applied to the switchboard mounting table 200 in the 12 o'clock direction. And transmitted to the intermediate plate 220, the shock wave transmitted to the intermediate plate 220 is absorbed by the fifth to eighth tension springs 292, 294, 296 and 298, which are upper tension springs. The shock wave may not be transmitted to the 230 or a minute shock wave may be transmitted. Therefore, the switchboard case disposed on the switchboard mounting table 200 is not adversely affected by the shock wave.

Although described above with reference to the embodiments, those skilled in the art can be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below. I can understand.

As described above, according to the present invention, even if a fluctuation occurs in the switchgear due to an earthquake or the like, damage to the internal electrical equipment can be prevented from occurring, thereby preventing the occurrence of a short circuit due to damage to the electrical equipment.

That is, even if fluctuations occur in the switchboard by earthquake or the like through earthquake-proof design in the switchboard mounting table supporting the switchboard case, the shock wave is prevented from being directly transmitted to various internal electric devices arranged in the switchboard case by the buffering action of the seismic design. It is possible to prevent the occurrence of a short circuit due to damage to the equipment.

100: switchboard case 200: switchboard mounting table
210: lower plate 220: middle plate
230: upper plate 252a: carriage
252b: Steel ball 252c: Square nut
252d: End Plate 252e: Lube Reservoir
252f: front steel 252g: screws
252h: lubricant nipples 262, 264: upper LM guides
242, 244, 246, 248: lower LM guides
252, 254, 256, 258: lower LM bearings
272, 274, 276, 278: upper LM bearings
282, 284, 286, 288: lower tension springs
292, 294, 296, 298: upper tension springs

Claims (5)

Switchboard case; And
And a switchboard mount for supporting the switchboard case and preventing shock waves from being applied to the switchboard case, wherein the switchboard mount includes:
A bottom plate fixed to the floor of the building;
An intermediate plate disposed on the lower plate;
An upper plate disposed on the intermediate plate and fastened to a bottom surface of the switchboard case;
A plurality of lower EL guides disposed in an X-axis direction on the lower plate;
A plurality of lower LM bearings slide-bonded to each of the lower LM guides and fastened to the intermediate plate;
A plurality of upper LM guides disposed in parallel with each other in a Y-axis direction on the upper part of the intermediate plate, and arranged perpendicularly to the lower LM guides when viewed on an XY plane;
A plurality of upper LM bearings slide-bonded to each of the intermediate LM guides and fastened to the upper plate;
A plurality of lower tension springs disposed in parallel with the lower plate, each of which has one side fastened to the lower plate and each of the other side fastened to the intermediate plate; And
A plurality of upper tension springs disposed in parallel with the intermediate plate, each of which has one side fastened to the intermediate plate and each of the other sides fastened to the upper plate,
And each of the lower tension springs is orthogonal to each of the upper tension springs when viewed on an XY plane. The method of claim 1, wherein the lower LM guides are arranged in two rows, the upper LM guides are arranged in two rows, when viewed from the XY plane the lower LM guides and the upper LM guides are arranged in a well sperm shape Switchgear having a seismic function, characterized in that. According to claim 1, wherein the lower tension springs are composed of four, arranged in a radial shape when viewed on the XY plane,
The upper tension springs are composed of four, the switchgear having a seismic function, characterized in that arranged in a rhombus shape when viewed on the XY plane. The method of claim 3, wherein the lower tension springs are composed of a first tension spring, a second tension spring, a third tension spring and a fourth tension spring,
The upper tension springs are composed of a fifth tension spring, a sixth tension spring, a seventh tension spring, and an eighth tension spring,
When viewed on an XY plane, the first tension spring and the fifth tension spring are orthogonal to each other, and the second tension spring and the sixth tension spring are orthogonal, and the third tension spring and the seventh tension spring are orthogonal to each other. And the fourth tension spring and the eighth tension spring orthogonal to each other. The method of claim 1, wherein the lower elm guide is composed of a first elm guide, a second elm guide, a third elm guide and a fourth elm guide, the upper elm guide is composed of a fifth elm guide and a six elm guide ,
And the fifth LM guide is orthogonal to the first and second LM guides, and the sixth LM guides are orthogonal to the third and fourth LM guides.

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